Wiper blade and method for manufacturing wiper blade

ABSTRACT

A wiper blade extends in a longitudinal direction and includes a blade rubber, a plate spring-like backing, and a rubber holder. The blade rubber wipes a wiped surface. The backing adds rigidity and elasticity to the blade rubber. The rubber holder holds an intermediate portion of the blade rubber in the longitudinal direction and an intermediate portion of the backing in the longitudinal direction. The rubber holder includes a backing accommodation slot that accommodates and holds the backing. The backing accommodation slot extends through the rubber holder in the longitudinal direction. The parting line is set in a middle section of the backing accommodation slot in the longitudinal direction.

RELATED APPLICATIONS

The present application is a National Phase entry of PCT Application No.

PCT/JP2014/067395, filed Jun. 30, 2014, which claims priority to JP 2013-188834, filed Sep. 11, 2013 and claims priority to JP 2013-215435, filed Oct. 16, 2013, all said applications being hereby incorporated herein by reference in their entireties.

TECHNICAL FIELD

The present invention relates to a wiper blade for a vehicle wiper and a method for manufacturing the wiper blade.

BACKGROUND ART

A conventional vehicle wiper is formed by a wiper arm and a wiper blade, which is coupled to the wiper arm. For example, patent document 1 describes a wiper blade including a coupling lever that holds a longitudinally intermediate portion of a blade rubber and a longitudinally intermediate portion of a backing. The coupling lever is formed from a resin and hollow in the longitudinal direction of the backing. The coupling lever surrounds the backing to accommodate and hold the backing.

PRIOR ART DOCUMENT Patent Document

Patent Document 1: Japanese Laid-Open Patent Publication No. 2013-63674

SUMMARY OF THE INVENTION

A coupling lever such as that described above is generally manufactured through injection molding. When molding a portion that accommodates the backing, injection molding is generally performed so that the portion accommodating the backing includes a single draft slope that extends continuously from one longitudinal end to the other longitudinal end of the portion. This facilitates the removal of a mold (slide core).

However, when a coupling lever having a draft slope such as that described above is coupled to a wiper arm, an urging force tends to be unevenly transmitted from the wiper arm to one longitudinal side of the backing. This adversely affects the wiping performance. It is an object of the present invention to provide a wiper blade and a method for manufacturing a rubber holder that facilitates even transmission of an urging force from a wiper arm to a backing in the longitudinal direction, thereby obtaining a favorable wiping performance.

To achieve the above object, one aspect of the present invention is a wiper blade that extends in a longitudinal direction and includes a blade rubber, a plate spring-like backing, and a rubber holder. The blade rubber is used to wipe a wiped surface. The backing adds rigidity and elasticity to the blade rubber. The rubber holder holds an intermediate portion of the blade rubber in the longitudinal direction and an intermediate portion of the backing in the longitudinal direction. The rubber holder includes a backing accommodation slot that accommodates and holds the backing. The backing accommodation slot extends through the rubber holder in the longitudinal direction. The parting line is set in a middle section of the backing accommodation slot in the longitudinal direction.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of one embodiment of a wiper according to the present invention.

FIG. 2 is an exploded perspective view of a portion of the wiper shown in FIG. 1.

FIG. 3 is a front view of a rubber holder, a backing, and a blade rubber of the embodiment when coupled.

FIG. 4 is a perspective view of a rubber holder and a clip shown in FIG. 2.

FIG. 5 is a front view of the rubber holder shown in FIG. 4.

FIG. 6 is a cross-sectional view of FIG. 5 taken along line A-A.

FIG. 7 is a schematic diagram illustrating draft slopes and rubber-side draft slopes of the embodiment.

FIG. 8 is a schematic diagram illustrating a further example of draft slopes and rubber-side draft slopes.

FIG. 9 is a cross-sectional view of a wiper blade of the embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

One embodiment of a vehicle wiper will now be described with reference to FIGS. 1 to 9. Here, “longitudinal direction” refers to the direction in which the long sides of a wiper blade 3 extend unless otherwise specified. The direction in which the long sides of a blade rubber 11, a backing 12, and a rubber holder 13 each extend is substantially the same as the longitudinal direction of the wiper blade 3.

As shown in FIG. 1, a wiper 1 for a vehicle is used to wipe off rain drops and the like from a windshield, which serves as a wiped surface of an automobile. The wiper 1 includes a wiper arm 2 and the wiper blade 3, which is coupled to the wiper arm 2. The drawing shows only the distal portion of the wiper arm 2. The basal portion of the wiper arm 2 is fixed to a pivot shaft (not shown), which is reciprocally rotated by a predetermined angle with the drive force of a wiper motor (not shown). The wiper arm 2 reciprocally pivots in accordance with the reciprocal rotation of the pivot shaft. The wiper arm 2 includes a distal coupling portion 4, which is urged by an urging mechanism (no shown) toward the windshield (wiped surface). The wiper blade 3 is coupled to the distal coupling portion 4 of the wiper arm 2.

As shown in FIGS. 2 and 3, the wiper blade 3 includes an elongated blade rubber 11, a plate spring-like backing 12, and a rubber holder 13. The wiped surface (windshield) is wiped with the blade rubber 11. The backing 12 provides the blade rubber 11 with rigidity (mainly, lateral rigidity, or rigidity in a wiping direction of the wiper blade 3) and elasticity (mainly, vertical elasticity, or elasticity of the blade rubber 11 toward the wiped surface). The rubber holder 13 holds a longitudinally intermediate portion of an upper portion 11 a of the blade rubber 11 and a longitudinally intermediate portion of the backing 12. In the upper portion 11 a of the blade rubber 11 and in the backing 12, the two longitudinal sides projecting out of the rubber holder 13 are covered by two flexible cases 14, and the two opposite ends are covered by caps 15, respectively (refer to FIG. 1). The backing 12 has substantially the same length as the blade rubber 11. The backing 12 is wider than the blade rubber 11. The backing 12 is curved (bulged outward toward a side opposite to the wiped surface and curved in the longitudinal direction) as viewed from the side. Thus, when the wiper blade 3 is urged toward a curved wiped surface (windshield), the backing 12 acts to force a wiping portion 1 lb of the blade rubber 11 located at a lower end against the wiped surface (windshield) in a favorable manner. In this case, the wiper case 14 is formed from a flexible resin material or a rubber material so as not to interfere with the action of the backing 12.

As shown in FIG. 2, the wiper blade 3 includes a clip 16. The clip 16 functions as a wiper arm coupling member that is coupled to the rubber holder 13 and pivotal about an axis extending in the lateral direction of the blade rubber 11. More specifically, the rubber holder 13 is formed from a resin material. A shaft insertion hole 13 a extends through the rubber holder 13 in the lateral direction at a longitudinally and vertically middle location. The shaft insertion hole 13 a functions as a support. The clip 16 is formed from a resin material. The clip 16 includes two side walls 16 a, an upper wall 16 b, and support shafts 16 c. The side walls 16 a extend along two side surfaces of the rubber holder 13, respectively. The upper wall 16 b connects the side walls 16 a and extends along an upper surface of the rubber holder 13. The support shafts 16 c coaxially project from inner surfaces of the side walls 16 a. When the support shafts 16 c are inserted into the shaft insertion hole 13 a, the clip 16 is pivotally supported relative to the rubber holder 13. The distal coupling portion 4 of the wiper arm 2 is fitted onto the clip 16.

The structure of the rubber holder 13 holding the backing 12 and the upper portion 11 a of the blade rubber 11 will now be described in detail.

As shown in FIGS. 3 to 6, a backing accommodation slot 13 b is formed in a lower portion of the rubber holder 13. The backing accommodation slot 13 b, which surrounds the backing 12, accommodates and holds the backing 12. The backing accommodation slot 13 b extends through the rubber holder 13 in the longitudinal direction.

The lower portion of the rubber holder 13 also includes a blade rubber accommodation slot 13 c that accommodates and holds the upper portion 11 a of the blade rubber 11 by surrounding the upper portion 11 a of the blade rubber 11. The blade rubber accommodation slot 13 c is spaced apart from and located below the backing accommodation slot 13 b. The blade rubber accommodation slot 13 c extends through the rubber holder 13 in the longitudinal direction. At a laterally middle location, the blade rubber accommodation slot 13 c opens at the lower portion of the rubber holder 13. In the present embodiment, the upper portion 11 a of the blade rubber 11 is smaller in width than the backing 12. Accordingly, the blade rubber accommodation slot 13 c is smaller in width than the backing accommodation slot 13 b.

The rubber holder 13 includes a wall 13 d between the backing accommodation slot 13 b and the blade rubber accommodation slot 13 c. The wall 13 d includes a slit 13 e extending vertically through a portion of the wall 13 d. The slit 13 e of the present embodiment is arranged in a middle location of the wall 13 d in the lateral direction and extends throughout the wall 13 d in the longitudinal direction.

As shown in FIG. 7, the backing accommodation slot 13 b includes draft slopes 13 f, 13 g. Joining surfaces of slide cores 21, 22, which form a mold for injection molding (described later), are located at the longitudinally middle section of the backing accommodation slot 13 b. The joining surfaces set a parting line P1 (refer to FIG. 6). The draft slopes 13 f, 13 g are located at opposite sides of the longitudinally middle section of the backing accommodation slot 13 b. The draft slopes 13 f, 13 g each extend at a descending gradient toward the outer side from the opposite sides of the middle section of the backing accommodation slot 13 b. In the present embodiment, the parting line P1 is set in range W1 that corresponds to the shaft insertion hole 13 a in the longitudinal direction of the backing accommodation slot 13 b. The draft slopes 13 f, 13 g extend from range W1 toward opposite sides in the longitudinal direction, that is, toward the outer sides. More specifically, the parting line P1 of the present embodiment is set at a position corresponding to (immediately below) an axis X of the shaft insertion hole 13 a. The draft slopes 13 f, 13 g extend from a longitudinal position corresponding to (immediately below) the axis X toward the opposite sides in the longitudinal direction. In the present embodiment, the position corresponding to (immediately below) the axis X conforms to the center position of the backing accommodation slot 13 b in the longitudinal direction. Additionally, in the present embodiment, each of the draft slopes 13 f, 13 g is straight and inclined relative to a straight line extending in the longitudinal direction as viewed from the side.

The blade rubber accommodation slot 13 c includes rubber-side draft slopes 13 h, 13 i. In the same manner as the backing accommodation slot 13 b, the joining surfaces of the slide cores 21, 22, which form the mold for injection molding, is located at the longitudinally middle section of the blade rubber accommodation slot 13 c. The joining surfaces set a rubber-side parting line P2 (refer to FIG. 6). The rubber-side draft slopes 13 h, 13 i are located at opposite sides of the longitudinally middle section of the blade rubber accommodation slot 13 c. The rubber-side draft slopes 13 h, 13 i each extend at a descending gradient toward the outer side from the opposite sides of the middle section of the blade rubber accommodation slot 13 c. In the same manner as the parting line P1 of the backing accommodation slot 13 b, the rubber-side parting line P2 of the present embodiment is set in range W1, which corresponds to the shaft insertion hole 13 a in the longitudinal direction. The rubber-side draft slopes 13 h, 13 i extend from a longitudinal position corresponding to (immediately below) the axis X of the blade rubber accommodation slot 13 c toward the opposite sides in the longitudinal direction, that is, toward the outer sides. To facilitate visual understanding, the gradients (angles relative to a straight line extending in the longitudinal direction) of the draft slopes 13 f, 13 g and the rubber-side draft slopes 13 h, 13 i are exaggerated in FIG. 7.

A method for manufacturing the rubber holder 13 will now be described. In the method for manufacturing the rubber holder 13, the backing accommodation slot 13 b is formed through injection molding. The injection molding forms the draft slopes 13 f, 13 g at the opposite sides of the longitudinally middle section of the backing accommodation slot 13 b. As described above, the draft slopes 13 f, 13 g each extend at a descending gradient toward the outer side. In the injection molding process of the present embodiment, the rubber-side draft slopes 13 h, 13 i are also simultaneously formed.

More specifically, as shown in FIG. 7, the two slide cores 21, 22 are used in the injection molding process. The slide core 21, which is located at one side (left side in FIG. 7), includes a first projection 21 a and a second projection 21 b, each tapered toward the other side (right side in FIG. 7) as viewed from the side, to form the draft slope 13 f and the rubber-side draft slope 13 h, which are respectively located at one side of the longitudinally middle sections of the backing accommodation slot 13 b and the blade rubber accommodation slot 13 c. Additionally, the slide core 22, which is located at the other side (right side in FIG. 7), includes a first projection 22 a and a second projection 22 b, each tapered toward the one side (left side in FIG. 7) as viewed from the side, to form the draft slope 13 g and the rubber-side draft slope 13 i, which are respectively located at the other side of the longitudinally middle sections of the backing accommodation slot 13 b and the blade rubber accommodation slot 13 c.

When the slide cores 21, 22 are in contact, the mold is filled with a molten resin. After the molten resin is cured, the slide cores 21, 22 are separated from each other. This manufactures the rubber holder 13 including the backing accommodation slot 13 b and the blade rubber accommodation slot 13 c.

The structure of the wiper case 14 will now be described.

As shown in FIG. 9, the blade rubber 11 includes a head 11 c, a narrow portion 11 d, the wiping portion 11 b, and a neck 11 e. The head 11 c and the narrow portion 11 d are arranged in the upper portion 11 a. The narrow portion 11 d has a smaller width than the head 11 c and extends downward. The wiping portion 11 b is arranged in a lower portion and used to wipe the wiped surface. The neck 11 e connects the wiping portion 11 b in a tiltable manner relative to the upper portion 11 a.

The wiper case 14 includes a case body 41 and a fin 42. The case body 41 is formed from a flexible resin material (polypropylene, in the present embodiment) and holds the upper portion 11 a (head 11 c) of the blade rubber 11 and the backing 12. The fin 42 is formed from a rubber material or an elastomer and fastened to an upper portion of the case body 41.

The case body 41 includes a tetragonal tubular receptacle 41 a, two lower extensions 41 b, and claws 41 c. The receptacle 41 a accommodates and holds the backing 12. The lower extensions 41 b extend downward from the receptacle 41 a and cover front and rear sides of the head 11 c, respectively. The claws 41 c respectively extend toward each other from lower ends of the lower extensions 41 b. The claws 41 c are opposed to a lower surface of the head 11 c and hold the head 11 c.

Each lower extension 41 b includes a thick portion 41 d located at a basal side of the lower extension 41 b. More specifically, the thick portions 41 d are laterally outer sections of the wiper case 14 and located at outer sides of the claws 41 c in the lateral direction of the wiper case 14. The thicknesses A1, A2 of the thick portions 41 d in the lateral direction (left-right direction in FIG. 9) are each greater than the thickness Z (in a heightwise direction) of a portion of the receptacle 41 a located between the backing 12 and the head 11 c. In other words, the thick portions 41 d limit deformation of the lower extensions 41 b relative to the basal ends of the lower extensions 41 b that would separate the claws 41 c, or from the upper ends of the portion connected to the receptacle 41 a. Each thick portion 41 d of the present embodiment includes an inclined surface 41 e that is inclined so that the thick portion 41 d widens toward the upper side. More specifically, in a cross-sectional view taken in a direction orthogonal to the longitudinal direction of the case body 41 (refer to FIG. 9), a straight line lying along a lower surface of a lower wall 41 g of the receptacle 41 a includes a point intersecting with a front outer surface of the case body 41, which is referred to as a front edge K, and a point intersecting with a rear outer surface of the case body 41, which is referred to as a rear edge Q. The front edge K and the rear edge Q of the receptacle 41 a are each connected to a base of the corresponding claw 41 c by line segments V, Y, respectively. The laterally inner sides of the line segments V, Y are filled with the flexible resin material to form a solid that defines the lower extensions 41 b including the thick portions 41 d. In this case, the thick portions 41 d include surfaces extending generally along the segment lines V, Y defining the inclined surfaces 41 e.

In the present embodiment, the lateral center line L1 of the receptacle 41 a is offset toward the rear of the vehicle (right side in FIG. 9) from the lateral center line L2 between the claws 41 c. That is, in the present embodiment, the backing 12 and the blade rubber 11 are held so that the lateral center line L1 of the backing 12 is located toward the rear of the vehicle (right side in FIG. 9) from the lateral center line L2 of the blade rubber 11.

Additionally, the receptacle 41 a includes a body fin 41 f at the vehicle front side (left side in FIG. 9). The body fin 41 f is inclined downward toward the vehicle front side. The body fin 41 f of the present embodiment extends to a vertically intermediate position of the lower extensions 41 b.

The fin 42 includes a fin inclined portion 42 a and a projection 42 b. The fin inclined portion 42 a is fastened to the upper surface of the receptacle 41 a excluding the body fin 41 f and is inclined upward toward the vehicle rear side. The projection 42 b projects upward at the vehicle rear side.

The body fin 41 f, the fin inclined portion 42 a, and the projection 42 b act to convert an air flow produced when the vehicle is travelling to a pressing force acting on the wiped surface (lower side).

The operation of the wiper 1, which is configured in the above manner, will now be described.

In the wiper 1, the wiper blade 3 (excluding the clip 16) is pivotal about the wiper arm 2 and the clip 16, which is fixed to the distal coupling portion 4 of the wiper blade 3. The distal coupling portion 4 of the wiper arm 2 is urged toward the windshield (wiped surface) by the urging mechanism (not shown). The urging force is transmitted to the blade rubber 11 through the clip 16, the rubber holder 13, and the backing 12. Consequently, the wiping portion 11 b, which is located at the lower end of the blade rubber 11, is pressed against the windshield (wiped surface) entirely in the longitudinal direction. In this case, the flexible wiper case 14 does not interfere with the operation of the curved backing 12. When the wiper arm 2 reciprocally pivots about the pivot shaft, the wiping operation is performed. The present embodiment has the advantages described below.

(1) The parting line P1 is set in the longitudinally middle section of the backing accommodation slot 13 b. Thus, the difference in a gap S, which results from the draft angle, between the backing accommodation slot 13 b and the backing 12 at the two longitudinal ends is smaller compared to when a parting line is set at one of the longitudinal ends. This facilitates even supporting of the backing 12 in the longitudinal direction. Consequently, urging force is easily and evenly transmitted from the coupled wiper arm 2 to the backing 12 in the longitudinal direction. This obtains a favorable wiping performance. Additionally, the maximum height H of the backing accommodation slot 13 b in the heightwise direction may decrease compared to when a parting line is set at one longitudinal end, which would form a single draft slope extending continuously from one end to the other end. This decreases, for example, the thickness of the wall 13 d, thereby reducing the size of the rubber holder 13 in the heightwise direction.

(2) The parting line P1 is set in the range W1, which corresponds to the shaft insertion hole 13 a in the longitudinal direction. The backing accommodation slot 13 b includes the draft slopes 13 f, 13 g located at the opposite sides of the longitudinally middle section of the backing accommodation slot 13 b. The draft slopes 13 f, 13 g each extend from the middle section of the backing accommodation slot 13 b toward the outer side. Thus, the gap S between the backing 12 and the backing accommodation slot 13 b is the smallest at the parting line P1, which is set in the range W1 corresponding to the shaft insertion hole 13 a. This further easily transmits even urging force from the wiper arm 2, which is coupled by the clip 16, to the backing 12 in the longitudinal direction. Consequently, the wiping performance may be further improved. Additionally, the draft slopes 13 f, 13 g of the present embodiment extend toward the longitudinally opposite sides from a position of the backing accommodation slot 13 b corresponding to (immediately below) the axis X of the shaft insertion hole 13 a in the longitudinal direction. Thus, the gap S between the backing accommodation slot 13 b and the backing 12 is the smallest at the position corresponding to (immediately below) the axis X of the shaft insertion hole 13 a. This further easily transmits even urging force from the wiper arm 2, which is coupled by the clip 16, to the backing 12 in the longitudinal direction. Consequently, the wiping performance may be further improved.

(3) The rubber-side parting line P2 is set in the longitudinally middle section of the blade rubber accommodation slot 13 c. Thus, the rubber-side draft slopes 13 h, 13 i extend from the longitudinally middle section of the blade rubber accommodation slot 13 c toward the longitudinally opposite sides. This decreases the maximum height of the blade rubber accommodation slot 13 c in the heightwise direction compared to when a rubber-side parting line is set at one end in the longitudinal direction. As a result, for example, the thickness of the wall 13 d may decrease, thereby reducing the rubber holder 13 in the heightwise size.

(4) The rubber holder 13 includes the wall 13 d between the backing accommodation slot 13 b and the blade rubber accommodation slot 13 c. The wall 13 d includes the slit 13 e extending vertically through a portion of the wall 13 d. Thus, it is relatively easy to form the wall 13 d with a small thickness dimension compared to a wall that lacks the slit 13 e. More specifically, when a wall lacking the slit 13 e is molded, resin would have to reach the entire wall. Thus, the design of a thin structure is difficult. However, the slit 13 e reduces the region (distance) that the resin needs to reach. This allows for a thin structure.

(5) The slit 13 e is located in the middle location of the wall 13 d in the lateral direction and extends throughout the wall 13 d in the longitudinal direction. This minimizes the area (extent) that the resin reaches while obtaining a structure in which the laterally opposite sides of the wall 13 d press the upper portion 11 a of the blade rubber 11 in a favorable manner. Thus, a thin structure may be obtained.

(6) Each lower extension 41 b includes the thick portion 41 d at the basal end side of the lower extension 41 b. The lateral thicknesses A1, A2 of the thick portions 41 d are each greater than the thickness Z of the portion of the receptacle 41 a located between the backing 12 and the head 11 c. This limits deformation, which, in turn, limits separation of the blade rubber 11, as compared to, for example, when there is no thick portion 41 d (e.g., prior art in which the thickness is uniformly small through the entire portions to follow the curve of a wiped surface). That is, when there is no thick portion 41 d (e.g., prior art in which the thickness is uniformly small through the entire portions), lower extensions would be easily deformed and separate the claws 41 c from the basal end (upper portion). However, such a situation may be limited. Consequently, separation of the blade rubber 11 from the wiper case 14 is limited, for example, when a great friction force is applied to the blade rubber 11 during a wiping operation or when applying force to the wiper to move to a lock-back position under a freezing environment in which the wiper blade 11 is fixed with the wiped surface.

(7) Each thick portion 41 d includes the inclined surface 41 e, which is inclined so that the width increases toward the upper side. This increases the rigidity toward the basal end portion (upper portion) of the lower extensions 41 b, from which deformation occurs.

Additionally, for example, when the wiper case 14 is entirely inclined relative to the wiped surface together with the wiper blade 3 during a wiping operation, contact of the wiper case 14 with the wiped surface is limited.

(8) The lateral center line L1 of the receptacle 41 a is offset from the lateral center line L2 between the claws 41 c toward the vehicle rear side. This reduces the portion of the receptacle 41 a bulged toward the front of the vehicle. As a result, pressure increases are limited that would be caused by air currents, which are produced when the vehicle travels, flowing toward the side (lower side) of the front-bulged wiper case 14, which is opposed to the wiped surface. This limits the separation of the wiper from the wiped surface. The above embodiment may be modified as follows.

In the above embodiment, each of the draft slopes 13 f, 13 g extends straight and is inclined relative to the longitudinal straight line as viewed from the side. However, each draft slope may have any shape as long as the rubber holder 13 may be smoothly removed from the mold. As shown in FIG. 8, a modified example may include draft slopes 31, 32 that curve and extend at a descending gradient from the parting line toward longitudinally outer sides as viewed from the side. Additionally, in this example (refer to FIG. 8), the rubber-side draft slopes 13 h, 13 i of the above embodiment are changed to rubber-side draft slopes 33, 34 that curve and extend at a descending gradient from the rubber-side parting line toward the longitudinally outer sides as viewed from the side. In this case, the slide cores 21, 22 of the above embodiment used in the manufacturing method are changed to slide cores 35, 36 that are shaped corresponding to the draft slopes 31, 32 and the rubber-side draft slopes 33, 34.

In the above embodiment, the draft slopes 13 f, 13 g extend from the position corresponding to (immediately below) the axis X of the shaft insertion hole 13 a in the longitudinal direction toward the longitudinally opposite sides. However, the draft slopes 13 f, 13 g may extend from another position in the longitudinally middle section of the backing accommodation slot 13 b toward opposite outer sides in the longitudinal direction. In this case, it is preferred to form the draft slopes from the range W1, which corresponds to the shaft insertion hole 13 a in the longitudinal direction, toward the longitudinal opposite sides. Additionally, in the above embodiment, the draft slopes 13 f, 13 g extend from the parting line P1. However, the origin of the draft slopes 13 f, 13 g does not have to conform to the parting line P1.

In the above embodiment, the rubber-side draft slopes 13 h, 13 i extend from the rubber-side parting line P2, which is set in a position corresponding to (immediately below) the axis X of the shaft insertion hole 13 a in the longitudinal direction, toward the longitudinally opposite sides. However, the rubber-side draft slopes 13 h, 13 i may extend from another position in the longitudinally middle section of the blade rubber accommodation slot 13 c toward opposite outer sides in the longitudinal direction.

In the above embodiment, the slit 13 e vertically extends through a portion of the wall 13 d between the backing accommodation slot 13 b and the blade rubber accommodation slot 13 c. However, the slit 13 e may be omitted from the structure. Additionally, in the above embodiment, the wall 13 d is formed by separately forming the blade rubber accommodation slot 13 c below the backing accommodation slot 13 b. However, the structure may be changed so that a blade rubber accommodation slot is continuously formed below a backing accommodation slot without being separated. In this case, the wall 13 d is not formed. Also, the upper portion 11 a of the blade rubber 11 is in contact with the backing 12.

In the present embodiment, the slit 13 e is formed in the laterally middle location of the wall 13 d throughout in the longitudinal direction. However, the slit 13 e may be formed in a different portion of the wall 13 d. For example, slits may be intermittently formed in the longitudinal direction.

In the above embodiment, the shaft insertion hole 13 a supports the clip 16 so that the clip 16 is pivotal about the axis extending in the lateral direction of the rubber holder. The rubber holder 13 includes the shaft insertion hole 13 a, which functions as a support. However, the rubber holder 13 may include a shaft functioning as a support that supports a clip (wiper arm coupling member).

The above embodiment includes the single backing 12. Instead, a wiper blade may include two backings. In this case, two opposite side surfaces of the upper portion 11 a of the blade rubber 11 may each include a longitudinal side groove. The longitudinal side grooves accommodate the backings. In the above embodiment, the thick portion 41 d includes the inclined surface 41 e that is inclined so that the width increases toward the upper side. However, the inclined surface 41 e may be omitted. For example, the thick portion may be uniformly thick in the lateral direction.

In the above embodiment, the lateral center line L1 of the receptacle 41 a is offset from the lateral center line L2 between the claws 41 c toward the vehicle rear side. Instead, for example, the lateral center line L1 of the receptacle 41 a may conform to the lateral center line L2 between the claws 41 c.

In the above embodiment, the wiper case 14 includes the fin 42. However, the wiper case 14 may exclude the fin 42 (include only the case body 41). 

1. A wiper blade that extends in a longitudinal direction, the wiper blade comprising: a blade rubber used to wipe a wiped surface: a plate spring-like backing that adds rigidity and elasticity to the blade rubber; and a rubber holder that holds an intermediate, portion of the blade rubber in the longitudinal direction and an intermediate portion of the backing in the longitudinal direction, wherein the rubber holder includes a backing accommodation slot that accommodates and holds the backing, the backing accommodation slot extends through the rubber holder in the longitudinal direction, and a. parting line is set in a middle section of the backing accommodation slot in the longitudinal direction.
 2. The wiper blade according to claim 1, wherein the rubber holder includes a support arranged at a portion of the rubber holder that corresponds to the middle section of the backing accommodation slot, the support pivotally supports a wiper arm coupling member about an axis that extends in a lateral direction of the rubber holder, the wiper arm coupling member is pivotally coupled to the rubber holder, the parting line is set in a range corresponding to the support in the longitudinal direction, the backing accommodation slot includes draft slopes located at opposite sides of the middle section of the backing accommodation slot in the longitudinal direction, and the draft slopes each extend from the middle section Of the backing accommodation slot toward an outer side.
 3. The wiper blade according to claim 2, wherein the draft slopes respectively extend from a position of the backing accommodation slot that corresponds to an axis of the support in the longitudinal direction toward opposite sides in the longitudinal direction.
 4. The wiper blade according to claim I, wherein the rubber holder includes a blade rubber accommodation slot that accommodates and holds an upper portion of the blade rubber, the blade rubber accommodation slot extends through the rubber holder in the longitudinal direction, the blade rubber accommodation slot includes a laterally middle location that opens in a lower portion of the rubber holder, a rubber-side parting line is set in a middle section of the blade rubber accommodation slot in the longitudinal direction.
 5. The wiper blade according to claim 1, wherein the rubber holder includes a blade rubber accommodation slot that accommodates and holds an upper portion of the blade rubber, the blade rubber accommodation slot is located separately from and below the backing accommodation slot, the blade rubber accommodation slot extends through the rubber holder in the longitudinal direction, the blade rubber accommodation slot includes a laterally middle location that opens in a lower portion of the rubber holder, the rubber holder includes a wall arranged between the backing accommodation slot and the blade rubber accommodation slot, and the wall includes a slit, that vertically extends through a portion of the wall.
 6. The wiper blade according to claim 5, wherein the slit is located in a middle location of the wall m a lateral direction and extends throughout the wall in the longitudinal direction.
 7. The wiper blade according to claim 1, wherein the blade rubber includes a head located in an upper portion, a narrow portion located in the upper portion, wherein the narrow portion has a smaller width than the head and extends downward, and a wiping portion located in a lower portion and used to wipe the wiped surface, the wiper blade further includes a wiper case located above the blade rubber, the wiper case holds the blade rubber and the backing, the wiper case includes a receptacle that accommodates and holds the backing, two lower extensions that extend downward from the receptacle and cover lateral sides of the head, and claws that respectively extend from lower ends of the two lower extensions toward a laterally inner side, wherein the claws are opposed to a lower surface of the head and hold the head, each or the lower extensions includes a thick portion located at a basal side of the lower extension, and each thick portion has a lateral thickness that is greater than a thickness of a portion of the receptacle located between the backing and the head.
 8. The wiper blade according to claim 7, wherein each thick portion includes an inclined surface that is inclined so that the thick portion widens toward an upper side.
 9. The wiper blade according to claim 7, wherein a lateral center line of the receptacle is offset from a lateral center line between the claws toward a vehicle rear side.
 10. The wiper blade according to claim 1, wherein the blade rubber includes a head located in an upper portion, a narrow portion located in the upper portion, wherein the narrow portion has a smaller width than the head and extends downward and a wiping portion located in a lower portion and used to wipe a wiped surface, the wiper blade further includes, a wiper case located above the blade rubber, the wiper case holds the blade rubber and the backing, the wiper case includes a receptacle that accommodates and holds the backing, two lower extensions that extend downward from the receptacle and cover lateral sides of the head, at and claws that respectively extend from lower ends of the two lower extensions toward a laterally inner side, wherein the claws are opposed to a lower surface of the head and hold the head, each of the lower extensions includes a thick portion located at an outer side of the lower extension, and the thick portions limit deformation of the lower extensions relative to basal ends of the lower extensions that would separate the claws.
 11. A method for manufacturing a wiper blade that extends in a longitudinal direction and includes a blade rubber used to wipe a wiped surface, a plate spring-like backing that adds rigidity and elasticity to the blade rubber, and a rubber holder that holds the blade rubber and the backing, the method comprising: forming the rubber holder that includes a backing accommodation slot through injection molding, wherein the backing accommodation slot accommodates and holds an intermediate portion of the backing in the longitudinal direction, and the backing accommodation slot extends through the rubber holder in the longitudinal direction; setting a parting line at a middle section of the backing accommodation slot in the longitudinal direction when forming the hacking accommodation slot; and arranging draft slopes at opposite sides of the middle section of the backing accommodation slot in the longitudinal direction during the injection molding, wherein the draft slopes each extend from the middle section of the backing accommodation slot toward an outer side. 